JP5521543B2 - Cryptographic recording medium - Google Patents

Description

  According to the present invention, in a normal state, a recorded image is concealed so that it cannot be visually recognized. At the time of restoration, the concealed shape information is visualized under a light source having a specific wavelength, and the original shape information can be read. The present invention relates to an encryption recording medium.

  In the normal state, there is a long-standing need to use information recorded in a concealed state when it is needed. For example, concealment seals and crimping postcards are familiar examples. These are one-time use (disposable) and are suitable for temporary use. On the other hand, while maintaining high secrecy when not in use, they can be restored by simple operation when used, and It is very difficult to meet the conflicting requirement of being reusable.

There is a visual decryption type encryption technique as one of the techniques for the above demand. This is achieved by processing the original image information into an image that cannot be visually recognized by dispersing it into a plurality of images (called shared images) composed of irregular patterns, and superimposing these shared images. This technique restores the original image information to a visible state.
For example, Patent Document 1 discloses a technique relating to the configuration and production of a recording medium that uses visual decryption encryption technology to conceal information without using a concealment layer or the like.
Various methods have been proposed for visual decryption encryption technology, share image generation means, and the like, and the principle and generation method are described in detail in Non-Patent Document 1, which is a pioneering paper.

JP 2001-118122 A

M.Naor and A.Shamir, "Visual Cryptography", Proc. Of Eurocrypt'94 May 1994

  As described above, the visual decryption encryption technology is advantageous in that it can be restored by visual manual operation. On the other hand, since the original image is restored by overlapping a plurality of share images, the share In order to restore the original image, it is necessary to precisely superimpose the plurality of media.

  FIG. 1 is a diagram illustrating a process of encryption and restoration using visual decryption encryption technology. For example, in a case where “T” of restored image 13 is to be obtained from two shared images as shown in FIG. The number of required media is 2, and a plurality of media are used. In addition, as shown in FIG. 2, since the images are superposed and visually observed, the overlapping surfaces of both media are smooth, and at least one of the media must be a transparent sheet like the transparent media a21. . Further, when two shared images are superimposed, there is a problem that it is difficult to distinguish between an image to be restored and a background because a white portion appears with a slight shift in overlap and a difference in density from the background becomes small.

  Therefore, the present invention can form two shared images on the same medium while using the visual decryption type encryption technology, and when restoring the original image, it is troublesome to strictly superimpose the two shared images. It is an object to provide an encryption recording medium that does not require an operation.

The present invention for solving the above problems
An encryption recording medium formed by superimposing a first encryption pattern and a second encryption pattern on a base material to generate an original image from an encryption image by a visual decryption secret sharing method,
The first cipher pattern and the second cipher pattern are arranged so that the dots constituting the pixels of the first cipher pattern and the dots constituting the pixels of the second cipher pattern do not overlap each other. ,
Against 4 × 4 dots of the original image, both the coarse and fine differences comprising at least a blank portion, is visibly displayed restored image and said Rukoto.

  According to the encryption recording medium of the present invention, since two share images can be formed on the same medium, the cost of the medium can be reduced, and an operation for overlaying the share images is not required. Further, since a transparent medium is not required and it is not necessary to have a sheet shape, there are no restrictions on the material and size of the medium.

Conceptual diagram of visual decryption encryption technology The figure which shows the state of restoration of the conventional visual decryption type encryption technology Schematic diagram of encryption pattern Figure showing a restored image Diagram showing pixel division The figure which shows the encryption pattern production | generation process of this invention The figure which shows the detail of the decompression | restoration image by the encryption pattern of this invention

Hereinafter, details of the present invention will be described with reference to FIGS.
FIG. 3 is a schematic view showing the encryption pattern generation process of the present invention in comparison with the encryption pattern generation process by the conventional visual decryption encryption technology. 3A illustrates an encryption pattern generation process using a conventional visual decryption encryption technique, and FIG. 3B illustrates an encryption pattern generation process according to the present invention, focusing on the pixels forming each pattern. It is a thing. In the following description, the former is referred to as a share pattern and the latter is referred to as a new encryption pattern in order to distinguish the encryption pattern according to the conventional visual decryption encryption technique and the encryption pattern according to the present invention.

First, a share pattern based on the conventional visual decryption encryption technology will be described.
As shown in FIG. 3A, the share pattern based on the conventional visual decryption encryption technology is a small region having an integer ratio (2 × 2 in the example) of pixels constituting the original image (original image pixel 30). It is generated by dividing into 35 and assigning white or black to each small area 35.
The share pattern generated in this way is a pixel constituting the share image A and the share image B. That is, the share pattern a32a and the share pattern a33a are the pixels of the share image A, and the share pattern b32b and the share pattern b33b are the pixels of the share image B. Then, when the share image A and the share image B are overlapped and the original image is restored, a pixel representing “white” such that the overlay of the two patterns such as the share pattern a 32 a and the share pattern b 32 b is the restored pixel 32. Thus, the overlapping of the two patterns of the share pattern a33a and the share pattern b33b becomes a pixel representing “black” like the restoration pixel 33.

Next, the new encryption pattern of the present invention will be described.
In generating a new cipher pattern of the present invention, as shown in FIG. 3B, first, a new divided pattern 41 for dividing the 2 × 2 small area shown in FIG. To do. A new cipher pattern a and a new cipher pattern b are generated by assigning white or black to each of the divided areas (referred to as dots). The process of generating a new encryption pattern will be described in detail later with reference to FIG.

  Two patterns such as a new restoration pattern 42 or a new restoration pattern 43 are formed by combining the new encryption patterns generated in this way. For example, when two patterns such as a new cipher pattern a42a and a new cipher pattern b42b are observed at the same time, a pixel having a dot distribution as in the new cipher pattern 42 is obtained, and similarly, a new cipher pattern a43a and a new cipher pattern b43b. When the two patterns are simultaneously observed, a pixel having a dot distribution as in the new cipher pattern 43 is obtained.

  FIG. 4 is a diagram showing the restored image by the new encryption pattern generated in this way while being compared with the restored image by the conventional visual decryption encryption technology, and FIG. 4 (A) shows the conventional visual decryption encryption. FIG. 4B shows a restored image based on the encryption pattern of the present invention.

FIGS. 4A and 4B show how the character part of “secret” can be distinguished from the background part and identified by combining two shared images.
FIG. 4A showing a restored image by the conventional visual decryption encryption technique observes an image that appears when two shared images are superimposed, and fills an irregular pattern representing “white” and “black”. The character portion 36 and the background portion 37 are distinguished by the pattern density difference.

  On the other hand, in the restored image using the encryption pattern of the present invention, the discrimination is made based on the difference in density between the pixel patterns of the character portion 46 and the background portion 47 as shown in FIG. That is, the state where the new restoration patterns 42 in FIG. 3B are gathered is visually recognized as a distribution of “coarse” pixels, and the collection of new restoration patterns 43 is visually recognized as a distribution of “dense” pixels. At this time, the two shared images are placed on the same medium, and the new restoration pattern 42 and the new restoration pattern 43 become visible when irradiated with two kinds of specific light sources described later.

FIG. 5 shows how the dots of the new encryption pattern of the present invention are generated by dividing the original pixel.
FIG. 5A is a diagram for explaining a template used for generating a new cipher pattern according to the present invention, and FIG. 5B is a diagram showing a process of generating a new cipher pattern using the template.
The template 50 in FIG. 5A is obtained by assigning “1” or “2” to the new divided pattern 41 in a staggered pattern, and the pixels 40 of the original image are changed by this “1” “2”. It can be divided into two cipher patterns without duplication.

Therefore, as shown in FIG. 5B, for example, “1” of the template 50 (that is, the template 51 “1”) is applied to the share pattern 32a by the conventional visual decryption encryption technology, and the share pattern a32a When the operation so as to enable the dot corresponding to "1", the dot pattern, such as the new encryption pattern a42a is obtained. Similarly, a new encryption pattern b42b is obtained by applying the template 52 “2” to the share pattern b32b, and a new encryption pattern 43b is obtained by applying the template 52 “2” to the share pattern b33b.

  As described above, by applying “1” and “2” of the template 50 to each pixel of the share image A and the share image B in the conventional visual decryption encryption technology, the first and second encryption patterns of the present invention are applied. These two types of encryption patterns can be generated.

FIG. 6 is a schematic diagram of the new cipher pattern of the present invention, and shows how the pixel 40 of the original image is divided into two pixels of the new cipher pattern a and the new cipher pattern b by the template 50 without overlapping dots.
As shown in FIG. 6, two combinations of a new restoration pattern 42 and a new restoration pattern 43 appear by superimposing the new encryption pattern a and the new encryption pattern b. In the figure, for the sake of understanding, the new restoration pattern a and the new restoration pattern b are distinguished by vertical and horizontal hatching.
Further, the new restoration pattern a and the new restoration pattern b are formed of two kinds of inks containing fluorescent materials that emit light with excitation light having different wavelengths, and each hatched dot in FIG. Represents that the light emitting state.

FIG. 7 is a diagram showing the details of the restored image by the encryption pattern of the present invention.
The restored image 70 indicates that both the first cipher pattern 71 and the second cipher pattern 72 are in a light-emitting state. As a result, the character portion 46 and the background portion 47 can be identified, and “s” The characters are visible. On the other hand, in the state where either the first cipher pattern 71 or the second cipher pattern 72 emits light alone, each irregular pattern appears, and the character portion 46 and the background portion 47 cannot be distinguished.
The enlarged boundary image 76 is an enlarged view of the boundary portion between the character portion 46 and the background portion 47. As a result, the dot distribution between the background portion and the character portion is “rough” and “dense”. You can see the difference.

In FIG. 7, the first cipher pattern 71 and the second cipher pattern 72 are expressed separately for the sake of explanation, but actually they are formed so as to overlap on the same medium.
The enlarged image 75 is an enlarged view of the dot pattern of the encryption pattern.

As described above, in order to obtain the restored image 70 from the first cipher pattern 71 and the second cipher pattern 72 formed on the same medium, in the cipher recording medium of the present invention, both patterns are respectively excited with excitation light having different wavelengths. It is formed by an ink containing a fluorescent substance that emits light.
For example, if A ink is emitted by the excitation light of the A light source and B ink is emitted by the excitation light of the B light source having a wavelength different from that of the A light source, the B ink is not emitted by the A light source, and the A ink is emitted by the B light source. Therefore, if the first and second cipher patterns are formed with such A ink and B ink, a restored image appears only when the A light source and the B light source are used at the same time. As a result, the restored image does not appear under the condition of any one of the A and B light sources as well as under visible light, and the confidentiality of the encryption recording medium is maintained.

As the A ink and B ink, a color material called fluorescent ink using a fluorescent pigment is suitable. As fluorescent pigments, ultraviolet light emitting phosphors that are excited by ultraviolet rays having a wavelength shorter than that of visible light and emit visible light are well known and widely used, but other infrared light emitting phosphors that are excited by infrared rays and emit visible light are known. (JP-A-2005-82770, “Infrared-Visible Conversion Phosphor”).
Here, simply touching on the infrared light emitting phosphor, the light emission of the ultraviolet light emitting phosphor is such that electrons or holes excited by light in the ultraviolet region return to a longer wavelength light (visible light) when returning to a lower energy level. ), The emission of infrared light emitting phosphors is a phenomenon in which the level is raised by two-step excitation that absorbs light from the state excited by infrared and rises to a higher level, and emits visible light. by.

  The first cipher pattern 71 and the second cipher pattern 72 may be formed by using fluorescent inks that emit light with different wavelengths of excitation light. One is ultraviolet light-emitting fluorescent ink, and the other is infrared light-emitting fluorescent ink. Since the restored image can be read only when both ultraviolet light and infrared light are used, it is more difficult for a third party to decipher. The fluorescent ink is colorless or translucent under visible light, and the pattern formed by the fluorescent ink is not visible under normal conditions (under visible light).

  As described above, according to the encryption recording medium of the present invention, since two secret images can be formed on the same medium, when obtaining a restored image, the operation of superimposing secret images is performed as in the past. do not need. In addition, since a transparent medium is not required and the medium is a single medium, the cost of the medium can be reduced, and since it is not necessary to be in the form of a sheet, there are no restrictions on the material and size of the medium.

10 Original image 11 Share image A
12 share image B
13 Restored image 21 Transparent medium a
22 Medium b
30 Original image pixel 31 Division pattern 32 Share pattern 33 Share pattern 36 Character part 37 Background part 40 Original image pixel 41 New division pattern 42 New restoration pattern 43 New restoration pattern 50 Template 70 Restoration image 71 First encryption pattern 72 2 encryption patterns

Claims (1)

An encryption recording medium formed by superimposing a first encryption pattern and a second encryption pattern on a base material to generate an original image from an encryption image by a visual decryption secret sharing method,
The first cipher pattern and the second cipher pattern are arranged so that the dots constituting the pixels of the first cipher pattern and the dots constituting the pixels of the second cipher pattern do not overlap each other. ,
Against 4 × 4 dots of the original image, both the coarse and fine differences including at least white space cipher recording medium characterized Rukoto is visibly displayed restored image.

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